Keyword search (4,163 papers available)

"Paraspinal muscle" Keyword-tagged Publications:

Title Authors PubMed ID
1 Aquatic exercise versus standard care on paraspinal muscle morphology and function in chronic low back pain patients: a randomized controlled trial Rosenstein B; Montpetit C; Vaillancourt N; Dover G; Weiss C; Papula LA; Melek A; Fortin M; 40328824
SOH
2 Comparison of Combined Motor Control Training and Isolated Extensor Strengthening Versus General Exercise on Lumbar Paraspinal Muscle Health and Associations With Patient-Reported Outcome Measures in Chronic Low Back Pain Patients: A Randomized Controlled Trial Rosenstein B; Rye M; Roussac A; Naghdi N; Macedo LG; Elliott J; DeMont R; Weber MH; Pepin V; Dover G; Fortin M; 40066720
SOH
3 The assessment of paraspinal muscle epimuscular fat in participants with and without low back pain: A case-control study Rosenstein B; Burdick J; Roussac A; Rye M; Naghdi N; Valentin S; Licka T; Sean M; Tétreault P; Elliott J; Fortin M; 38280825
HKAP
4 Thresholding approaches for estimating paraspinal muscle fat infiltration using T1- and T2-weighted MRI: Comparative analysis using water-fat MRI Ornowski J; Dziesinski L; Hess M; Krug R; Fortin M; Torres-Espin A; Majumdar S; Pedoia V; Bonnheim NB; Bailey JF; 38222819
HKAP
5 Effect of aquatic exercise versus standard care on paraspinal and gluteal muscles morphology in individuals with chronic low back pain: a randomized controlled trial protocol Rosenstein B; Montpetit C; Vaillancourt N; Dover G; Khalini-Mahani N; Weiss C; Papula LA; Melek A; Fortin M; 38110922
SOH
6 The Effects of Combined Motor Control and Isolated Extensor Strengthening versus General Exercise on Paraspinal Muscle Morphology, Composition, and Function in Patients with Chronic Low Back Pain: A Randomized Controlled Trial Fortin M; Rye M; Roussac A; Montpetit C; Burdick J; Naghdi N; Rosenstein B; Bertrand C; Macedo LG; Elliott JM; Dover G; DeMont R; Weber MH; Pepin V; 37762861
PERFORM
7 Comparison of paraspinal muscle composition measurements using IDEAL fat-water and T2-weighted MR images Sara Masi 36997912
PERFORM
8 Paraspinal muscle imaging measurements for common spinal disorders: review and consensus-based recommendations from the ISSLS degenerative spinal phenotypes group Hodges PW; Bailey JF; Fortin M; Battié MC; 34542672
HKAP
9 LUMINOUS database: lumbar multifidus muscle segmentation from ultrasound images Belasso CJ; Behboodi B; Benali H; Boily M; Rivaz H; Fortin M; 33097024
PERFORM
10 Lumbar Multifidus Muscle Characteristics, Body Composition, and Injury in University Rugby Players Lévesque J; Rivaz H; Rizk A; Frenette S; Boily M; Fortin M; 32997748
PERFORM
11 Evaluation of an automated thresholding algorithm for the quantification of paraspinal muscle composition from MRI images. Fortin M, Omidyeganeh M, Battié MC, Ahmad O, Rivaz H 28532491
PERFORM
12 Quantitative Magnetic Resonance Imaging Analysis of the Cervical Spine Extensor Muscles: Intrarater and Interrater Reliability of a Novice and an Experienced Rater. Fortin M, Dobrescu O, Jarzem P, Ouellet J, Weber MH 29503688
PERFORM
13 Population-averaged MRI atlases for automated image processing and assessments of lumbar paraspinal muscles. Xiao Y, Fortin M, Battié MC, Rivaz H 30051147
PERFORM

 

Title:Evaluation of an automated thresholding algorithm for the quantification of paraspinal muscle composition from MRI images.
Authors:Fortin MOmidyeganeh MBattié MCAhmad ORivaz H
Link:https://www.ncbi.nlm.nih.gov/pubmed/28532491?dopt=Abstract
DOI:10.1186/s12938-017-0350-y
Publication:Biomedical engineering online
Keywords:Automated algorithmErector spinaeFatty infiltrationMagnetic resonance imagingMultifidusParaspinal muscle
PMID:28532491 Category:Biomed Eng Online Date Added:2019-04-15
Dept Affiliation: PERFORM
1 PERFORM Centre, Concordia University, 7200 Sherbrooke W, Montreal, QC, H4B 1R6, Canada.
2 Department of Electrical Engineering, Engineering, Computer Science and Visual Arts Integrated Complex, Concordia University, 1515 Ste-Catherine W. Street, Montreal, QC, H3G 2W1, Canada.
3 Common Spinal Disorders Research Group, Faculty of Rehabilitation Medicine University of Alberta, 8205-114 Street, Edmonton, AB, T6G 2G4, Canada.
4 PERFORM Centre, Concordia University, 7200 Sherbrooke W, Montreal, QC, H4B 1R6, Canada. hrivaz@ece.concordia.ca.
5 Department of Electrical Engineering, Engineering, Computer Science and Visual Arts Integrated Complex, Concordia University, 1515 Ste-Catherine W. Street, Montreal, QC, H3G 2W1, Canada. hrivaz@ece.concordia.ca.

Description:

Evaluation of an automated thresholding algorithm for the quantification of paraspinal muscle composition from MRI images.

Biomed Eng Online. 2017 May 22;16(1):61

Authors: Fortin M, Omidyeganeh M, Battié MC, Ahmad O, Rivaz H

Abstract

BACKGROUND: The imaging assessment of paraspinal muscle morphology and fatty infiltration has gained considerable attention in the past decades, with reports suggesting an association between muscle degenerative changes and low back pain (LBP). To date, qualitative and quantitative approaches have been used to assess paraspinal muscle composition. Though highly reliable, manual thresholding techniques are time consuming and not always feasible in a clinical setting. The tedious and rater-dependent nature of such manual thresholding techniques provides the impetus for the development of automated or semi-automated segmentation methods. The purpose of the present study was to develop and evaluate an automated thresholding algorithm for the assessment of paraspinal muscle composition. The reliability and validity of the muscle measurements using the new automated thresholding algorithm were investigated through repeated measurements and comparison with measurements from an established, highly reliable manual thresholding technique.

METHODS: Magnetic resonance images of 30 patients with LBP were randomly selected cohort of patients participating in a project on commonly diagnosed lumbar pathologies in patients attending spine surgeon clinics. A series of T2-weighted MR images were used to train the algorithm; preprocessing techniques including adaptive histogram equalization method image adjustment scheme were used to enhance the quality and contrast of the images. All muscle measurements were repeated twice using a manual thresholding technique and the novel automated thresholding algorithm, from axial T2-weigthed images, at least 5 days apart. The rater was blinded to all earlier measurements. Inter-method agreement and intra-rater reliability for each measurement method were assessed. The study did not received external funding and the authors have no disclosures.

RESULTS: There was excellent agreement between the two methods with inter-method reliability coefficients (intraclass correlation coefficients) varying from 0.79 to 0.99. Bland and Altman plots further confirmed the agreement between the two methods. Intra-rater reliability and standard error of measurements were comparable between methods, with reliability coefficient varying between 0.95 and 0.99 for the manual thresholding and 0.97-0.99 for the automated algorithm.

CONCLUSION: The proposed automated thresholding algorithm to assess paraspinal muscle size and composition measurements was highly reliable, with excellent agreement with the reference manual thresholding method.

PMID: 28532491 [PubMed - indexed for MEDLINE]




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